Abstract
Rubber trees in southern China are often impacted by natural disturbances that can result in a tilted tree body. Accurate crown segmentation for individual rubber trees from scanned point clouds is an essential prerequisite for accurate tree parameter retrieval. In this paper, three plots of different rubber tree clones, PR107, CATAS 7-20-59, and CATAS 8-7-9, were taken as the study subjects. Through data collection using ground-based mobile light detection and ranging (LiDAR), a voxelisation method based on the scanned tree trunk data was proposed, and deep images (i.e., images normally used for deep learning) were generated through frontal and lateral projection transform of point clouds in each voxel with a length of 8 m and a width of 3 m. These images provided the training and testing samples for the faster region-based convolutional neural network (Faster R-CNN) of deep learning. Consequently, the Faster R-CNN combined with the generated training samples comprising 802 deep images with pre-marked trunk locations was trained to automatically recognize the trunk locations in the testing samples, which comprised 359 deep images. Finally, the point clouds for the lower parts of each trunk were extracted through back-projection transform from the recognized trunk locations in the testing samples and used as the seed points for the region’s growing algorithm to accomplish individual rubber tree crown segmentation. Compared with the visual inspection results, the recognition rate of our method reached 100% for the deep images of the testing samples when the images contained one or two trunks or the trunk information was slightly occluded by leaves. For the complicated cases, i.e., multiple trunks or overlapping trunks in one deep image or a trunk appearing in two adjacent deep images, the recognition accuracy of our method was greater than 90%. Our work represents a new method that combines a deep learning framework with point cloud processing for individual rubber tree crown segmentation based on ground-based mobile LiDAR scanned data.
Highlights
IntroductionArg.) trees, which are a widely planted hardwood genus in tropical areas, are important sources of natural rubber and wood
For crooked rubber trees caused by long-term hurricane disturbances, a deep-learning method based on the scanned point clouds collected by man-portable light detection and ranging (LiDAR) was designed to detect the location of rubber tree trunks and accomplish individual rubber tree crown segmentation
Through the voxelisation of the scanned trunk points and projection transform from the scanned points, a total of 802 deep images providing the trunk information for three rubber tree plots of different clones was generated, which are used as the training samples for optimisation of the convolutional networks and related parameter selection
Summary
Arg.) trees, which are a widely planted hardwood genus in tropical areas, are important sources of natural rubber and wood. As China’s largest rubber production base, has nearly 8 million acres of rubber forest, forming the largest artificial ecosystem [1]. Due to its geographical location, Hainan Island’s trees are frequently disturbed by typhoons and chilling injuries [2]. Typhoons that occur over a short period can cause serious damage, such as trunk and branch breakage and uprooting. Chilling damage is usually accompanied by long-term secondary damage of the rubber plantation, such as tree dieback, bark splitting, and bleeding [2]. To determine the wind resistance performance index of rubber trees and cultivate strong, resistant varieties, an accurate algorithm for individual rubber tree segmentation is indispensable for obtaining the structural parameters and dynamic change information of rubber trees of different clones [3]
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